KR20230007824A - Dish Washer - Google Patents

Abstract

The present invention relates to a dish washer. The dish washer of the present invention includes: a tub; a supply fan supplying external air to the tub; a heating duct disposed below the tub and having a heater to heat the air flowing from the supply fan; a supply duct connected to the heating duct and supplying air flowing from the heating duct to one side of the tub; and a water collecting device disposed below the heating duct and storing condensed water flowing from the supply duct.

Description

Dishwasher {Dish Washer}

The present invention relates to a dishwasher, and more particularly, to a dishwasher for supplying external air into a tub.

A dishwasher cleans, rinses, and dries dishes to provide convenience to users by treating contaminants on dishes and drying them.

The process of drying the dishes may be performed by heating water stored in the dishwasher and supplying high-temperature steam to the dishes, or may be performed by supplying external dry air into the tub.

Registered Patent No. KR10-1792513 discloses a structure in which external air is heated by a heater and supplied to the inside of the tub. However, when outside air is introduced in the above structure, it is possible to heat the outside air from the supply device and supply it to the tub.

However, when the supply device does not operate, humid air inside the tub may flow into the supply device. Moist air introduced from the tub into the supply device generates condensate, and the condensed water flows into a heater or fan disposed therein and rusts the heater or fan, which may cause an operation error.

An object to be solved by the present invention is to provide a dishwasher that minimizes the effect of condensate water generated from humid air flowing into the supply device on the internal structure of the supply device.

Another object of the present invention is to provide a dishwasher capable of detecting an excessive amount of condensed water generated in a supply device.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a dishwasher according to an embodiment of the present invention includes a tub, a supply fan for supplying external air to the tub, and a supply fan disposed below the tub and heating air flowing from the supply fan. A heating duct connected to the heating duct and supplying air flowing from the heating duct to one side of the tub, disposed below the heating duct, and storing condensed water flowing from the supply duct. It is possible to prevent moisture from entering the heater disposed in the heating duct by including a water collecting device.

A communication hole communicating with the water collector is formed in the heating duct, and the communication hole is disposed closer to the supply duct than the supply fan, thereby minimizing the inflow of moisture into a heater disposed in the heating duct. .

An overflow hole is formed on one side of the water collecting device to communicate the inside and the outside, so that water flowing into the water collecting device can be prevented from flowing backward to the heating duct.

A water level sensor is included on one side of the water collecting device to detect the level of the condensed water stored therein, and the water level sensor is disposed above the overflow hole, so that the inflow of the condensed water flowing into the water collecting device is rapidly increased. can detect that

The heating duct includes a bottom plate disposed below the heater and having a communication hole formed at one side thereof, and the bottom plate is disposed on an upstream side of the air flow direction based on the communication hole. And, a second bottom plate disposed on the downstream side of the air flow direction based on the communication hole, wherein the second bottom plate is inclined downward as it is adjacent to the communication hole, condensate flowing into the heating duct is discharged to the water collecting device, and the heated air flowing through the heating duct can stably flow into the supply duct.

A communication hole is formed at the lower side of the supply duct to send the condensed water flowing into the supply duct to the water collecting device, so that the condensed water generated from the air flowing in from the tub is not sent to the heating duct but to the water collecting device.

The supply duct includes a first supply duct disposed in the lateral direction of the tub and forming an ascending passage, and a second supply duct having a bent connection passage to connect the heating duct having a horizontal passage and the first supply duct. A duct and a connection body disposed at an end of the second supply duct and having an opening communicating with the inside of the heating duct, wherein the communication hole is formed at a lower side of the second supply duct and is generated through the supply duct. The condensed liquor can be sent to the water collector.

The communication hole is formed adjacent to the connection body, and a step is formed in the connection body at a portion connected to the second supply duct to prevent condensate flowing along the supply duct from entering the heating duct. can do.

A communication hole is formed below the second supply duct, and a flow guide is disposed upstream of the communication hole to guide the air flowing from the heating duct to the first supply duct. It flows into the supply duct, and the condensed water flowing from the first supply duct may flow into the water collecting device.

A bent connection passage is formed inside the second supply duct, and the second supply duct includes an upper wall disposed above the connection passage and a lower wall disposed below the connection passage, The upper wall includes an upper vertical wall extending in a vertical direction, an upper horizontal wall connected to the heating duct and extending in a horizontal direction, and an upper bending wall connecting the upper vertical wall and the upper horizontal wall, The lower wall includes a lower vertical wall formed in a direction parallel to the upper vertical wall, a lower horizontal wall disposed downward in parallel with the upper horizontal wall, and a lower bending wall connecting the lower vertical wall and the lower horizontal wall. Including, an inner protruding rib protruding downward is disposed at a lower end of the upper vertical wall, so that condensed water flowing along the supply duct can flow to the lower side of the supply duct.

The inner protruding rib extends in the left and right directions and protrudes downward in the form of a screw thread, so that the inner protruding rib can minimize air flow obstruction.

A flow guider is disposed on the lower horizontal wall, the communication hole is formed downstream of the flow guider, and the interval at which the inner protruding rib is spaced from the opening is longer than the interval at which the end of the flow guider is spaced from the opening Formed, the condensed water flowing along the supply duct may flow to the water collecting device through the communication hole.

Details of other embodiments are included in the detailed description and drawings.

According to the dishwasher of the present invention, one or more of the following effects are provided.

First, there is an advantage in that it is possible to minimize the inflow of moisture into a heater or a supply fan by collecting condensate generated from humid air flowing into a supply device into a separate space. This structure can prevent the life of the heater or the supply fan from being shortened.

Second, there is an advantage in that a rapid inflow of condensate into the water collecting device can be detected in advance by arranging the overflow hole and the water level sensor at a height difference in the water collecting device in which the condensed water is stored. It is possible to prevent condensed water collected in the water collecting device from flowing back to the heating duct.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of a dishwasher according to a first embodiment of the present invention.
2 is a view for explaining configurations of a tub, a supply device, and an exhaust device of a dish washing machine according to a first embodiment of the present invention.
3 is a perspective view of the supply device of the dishwasher according to the first embodiment of the present invention.
4 is a side perspective view for explaining the structure and arrangement of the heating duct and water collecting device of the supply device according to the first embodiment of the present invention.
5 is a side view of a supply device according to a first embodiment of the present invention.
6 is a side view of a supply device according to a second embodiment of the present invention.
7 is a side view of a supply device according to a third embodiment of the present invention.
8 is a side view of a supply device according to a fourth embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, the present invention will be described with reference to drawings for explaining a dishwasher according to embodiments of the present invention.

Referring to FIGS. 1 and 2, the dishwasher 1 of the present invention forms an outer shape, a case 10 with an open front, and a washing space disposed inside the case 10 and in which dishes are disposed. The tub 12 forming (not shown), the door 20 opening and closing the front of the tub 12, and the space disposed below the tub 12 and in which the washing water treatment component is disposed between the tub 12 and the tub 12 It includes a base 14 to form and a lower cover 16 disposed to cover the front surface of the base 14.

A washing space is formed inside the tub 12 . A rack (not shown) for storing dishes and a plurality of spray nozzles (not shown) for spraying washing water into the inner space of the tub 12 may be disposed inside the tub 12 .

Referring to FIG. 2, the dishwasher 1 includes an exhaust device 50 for discharging air inside the tub 12 to the outside, and a supply device 100 for supplying external air to the washing space inside the tub 12. ). The exhaust device 50 is disposed on the door 20 to mix the air inside the tub 12 or the air inside the tub 12 with outside air and discharge the mixture to the outside. The supply device 100 is disposed on the side and the lower side of the tub 12 to heat external air and supply it to the tub 12 .

Referring to FIG. 3 , the supply device 100 includes a supply fan 102 for supplying outside air to the tub 12, a supply fan housing 104 forming a space in which the supply fan 102 is disposed, and a supply fan housing. (104) A heating duct 106 disposed on one side to guide the flowing air, a heater 108 disposed inside the heating duct 106 to heat the flowing air, connected in the heating duct 106, and heated A supply duct 114 connecting the duct 106 and one side of the tub 12, and a water collecting device 140 disposed below the heating duct 106 and storing condensed water flowing from the supply duct 114.

Referring to FIG. 3 , the supply fan housing 104 is disposed below the tub 12 . The supply fan housing 104 has a fan inlet (not shown) formed on the lower side, and a fan outlet connected to the heating duct 106 is formed on one side of the circumferential surface.

The heating duct 106 is disposed below the tub 12 . A heater 108 is disposed inside the heating duct 106 to heat the air flowing from the supply fan housing 104 .

The heater 108 may be formed in a coil shape inside the heating duct 106 . The heating duct 106 has a structure extending in a direction in which the radial center of the coiled heater 108 extends. The heating duct 106 forms a flow path in the direction in which the center of the coil extends. Thus, the air flowing through the heating duct 106 can be evenly heated as a whole. In addition, the air discharged from the heating duct 106 may have an even temperature distribution in the upper, lower, left, and right directions of the discharge end.

The heater 108 is a sheath heater type and has a tubular shape to maximize spatial efficiency within the heating duct 106 . The heating duct 106 has a straight flow path. The center line of the heating duct 106 and the heater 108 coincide, so that a uniform wind speed can be applied to the surface of the heater.

In the heater 108, the terminal unit 110 may be disposed on one side of the heating duct 106. One side of the heating duct 106 where the terminal unit 110 is disposed may have a relatively low temperature under the same wind speed condition. A thermostat 112 for detecting whether the heater 108 is overheated may be disposed on one side of the heating duct 106 where the terminal unit 110 is disposed. Since the thermostat 112 is disposed in a region where the temperature is relatively low in the heating duct 106, the temperature range of the heater 108 sensed by the thermostat 112 can be set low. This can detect abnormal operation of the heater 108 quickly.

An expansion duct 105 may be disposed between the supply fan housing 104 and the heating duct 106 to expand the cross-sectional area of the passage. In the expansion duct 105, the cross-sectional area of the passage may be expanded in the vertical direction from the discharge end of the supply fan housing 104. In the heating duct 106 , the cross-sectional area of the passage expanded in the expansion duct 105 may be maintained.

The supply duct 114 includes a first supply duct 116 disposed in the lateral direction of the tub 12 and forming an ascending passage 116a, a heating duct 106 having a horizontal passage 106a, and an ascending passage ( 116a) is disposed at the end of the second supply duct 118 having a connection passage 118a bent to connect the first supply duct 116 formed thereon, and the heating duct 106 It includes a connection body 120 having an opening 120a communicating with the inside of the ). The second supply duct 118 may allow air discharged from the heating duct 106 to flow upward through the connection passage 118a.

Inside the first supply duct 116, an upstream passage 116a for sending the air discharged from the heating duct 106 upward, and a change passage for changing the flow direction of the air flowing through the upstream passage 116a downward ( 116b), a downflow passage 116c is formed to flow the air flowing through the change passage 116b downward.

The supply duct 114 and the tub 12 may communicate with each other at the lower end of the downflow path 116c. Accordingly, it is possible to prevent water scattered inside the tub 12 from flowing into the supply duct 114 and flowing into the heater 108 inside the heating duct 106 .

A guide rib 117 may be formed inside the first supply duct 116 to guide the flow of air in the direction in which the flow path extends.

The water collecting device 140 is disposed below the heating duct 106 . A communication hole 122 communicating with the heating duct 106 is formed in the water collecting device 140 .

The communication hole 122 is disposed on the downstream side of the heating duct 106 . The communication hole 122 is disposed closer to the supply duct 114 than to the supply fan housing 104 .

The bottom plate 107 of the heating duct 106 is based on the first bottom plate 107a disposed upstream in the air flow direction with respect to the communication hole 122 and the flow of air based on the communication hole 122 and a second bottom plate 107b disposed on the downstream side in the direction.

An extension plate 121 extending from the connection body 120 is disposed below the second bottom plate 107b. The extension plate 121 may cover one upper side of the water collecting device 140 .

The water collecting device 140 forms a space for storing condensed water.

On the upper side of the water collecting device 140, a water collecting device cover 141 is disposed below the first bottom plate 107a and covers one upper side of the water collecting device 140. The water collecting device cover 141 is spaced apart from the extension plate 121 . Between the water collecting device cover 141 and the extension plate 121, an inflow hole 146 communicating the inside of the heating duct 106 and the inside of the water collecting device 140 is formed. The inlet hole 146 is disposed below the communication hole 122 .

An overflow hole 142 is formed on one side of the water collecting device 140 to prevent condensed water stored in the water collecting device 140 from flowing back to the heating duct 106 through the communication hole 122 . The water collecting device 140 includes a water level sensor 144 that detects that the level of the condensed water stored in the water collecting device 140 is higher than the overflow hole 142 .

As the water level sensor 144, an electrode sensor may be used. In the water level sensor 144, the amount of condensed water flowing into the communication hole 122 is greater than the amount of condensed water drained into the overflow hole 142, so that the water stored in the water collecting device 140 flows back into the heating duct 106. can detect that

The water level sensor 144 is disposed on the upper side of the water collecting device 140, and the overflow hole 142 is disposed below the water level sensor 144.

Hereinafter, the heating duct 106 and the water collector 140 according to the second embodiment of the present invention will be described with reference to FIG. 6 .

The heating duct 106 according to the second embodiment is different from the first embodiment in the bottom plate 107.

The second bottom plate 107b may be formed to be inclined downward as it is closer to the communication hole 122 . The second bottom plate 107b may guide the condensed water flowing from the supply duct 114 to the water collecting device 140 through the communication hole 122 . An end of the second bottom plate 107b may extend to be disposed below the first bottom plate 107a.

The structure of the first bottom plate 107a and the second bottom plate 107b can minimize resistance of air flowing through the heating duct 106 . The structures of the first bottom plate 107a and the second bottom plate 107b may guide the condensate flowing into the heating duct 106 to the water collecting device 140 .

An inflow hole 146 may be formed in the upper side plate of the water collecting device 140 below the communication hole 122 formed between the first bottom plate 107a and the second bottom plate 107b.

Hereinafter, the supply duct 114 and the water collector 140 according to the third embodiment of the present invention will be described with reference to FIG. 7 .

The water collecting device 140 is disposed below the heating duct 106 . The water collecting device 140 is disposed below a portion of the heating duct 106 and the supply duct 114 .

A communication hole 122 is formed at the lower side of the supply duct 114 to send condensed water to the water collector 140 . A communication hole 122 is formed at a lower end of the supply duct 114 connected to the heating duct 106 . The water collecting device 140 is disposed below the supply duct 114, and an inflow hole 146 is formed at a position corresponding to the communication hole 122.

The supply duct 114 includes a first supply duct 116 disposed in the lateral direction of the tub 12 and forming an ascending passage 116a, a heating duct 106 having a horizontal passage 106a, and an ascending passage ( 116a) is disposed at the end of the second supply duct 118 having a connection passage 118a bent to connect the first supply duct 116 formed thereon, and the heating duct 106 It includes a connection body 120 having an opening 120a communicating with the inside of the ).

The communication hole 122 may be formed on the lower side of the second supply duct 118 . The communication hole 122 may be formed at a position adjacent to the connection body 120 . A step 120b may be formed in a region extending from the second supply duct 118 to the connection body 120 . Therefore, the condensed water flowing downward along the second supply duct 118 does not flow to the heating duct 106 and may flow to the water collecting device 140 through the communication hole 122 .

The water collecting device 140 is disposed below the supply duct 114 and the heating duct 106 to store condensed water introduced through the communication hole 122 . That is, since the condensed water does not flow into the heating duct 106 where the heater 108 is disposed, the inflow of moisture into the heater 108 can be minimized.

Hereinafter, the supply duct 114 and the water collector 140 according to the fourth embodiment of the present invention will be described with reference to FIG. 8 .

The supply duct 114 includes a first supply duct 116 disposed in the lateral direction of the tub 12 and forming an ascending passage 116a, a heating duct 106 having a horizontal passage 106a, and an ascending passage ( 116a) is disposed at the end of the second supply duct 118 having a connection passage 118a bent to connect the first supply duct 116 formed thereon, and the heating duct 106 It includes a connection body 120 having an opening 120a communicating with the inside of the ).

A communication hole 122 is formed on the lower side of the second supply duct 118 . A flow guider 124 is disposed upstream of the communication hole 122 to guide air flowing from the heating duct 106 to the first supply duct 116 .

The flow guider 124 is disposed under the second supply duct 118. A communication hole 122 is formed downstream of the flow guider 124 . The flow guider 124 has an inclined surface protruding upward in the direction of air flow. The downstream end 124a of the flow guider 124 may be formed to be stepped with the surface where the second supply duct 118 is formed.

Inside the second supply duct 118, a bent connection passage 118a is formed. The second supply duct 118 is disposed on both sides of the upper wall 130 disposed above the connection passage 118a, the lower wall 132 disposed below the connection passage 118a, and the connection passage 118a. It may include side walls 134 to be. The upper wall 130 includes an upper vertical wall 130a extending in a vertical direction, an upper horizontal wall 130b connected to the heating duct 106 and extending in a horizontal direction, and an upper vertical wall 130a and an upper horizontal wall 130a. It includes an upper bending wall 130c connecting the wall 130b. The lower wall 132 includes a lower vertical wall 132a formed in a direction parallel to the upper vertical wall 130a, a lower horizontal wall 132b disposed in parallel to the lower side of the upper horizontal wall 130b, and a lower vertical wall ( 132a) and a lower bending wall 132c connecting the lower horizontal wall 132b.

A communication hole 122 is formed in the lower horizontal wall 132b. A flow guider 124 is disposed on the lower horizontal wall 132b.

At the lower end of the upper vertical wall 130a, an inner protruding rib 136 protruding downward is disposed. The inner protruding rib 136 may extend downward from the upper vertical wall 130a. The inner protruding ribs 136 are disposed to extend to both sides. The inner protruding rib 136 may have a screw thread shape to minimize flow resistance of air flowing from the heating duct 106 .

The distance L1 between the inner protruding rib 136 and the opening 120a is longer than the distance L2 between the end 124a of the flow guider 124 and the opening 120a. Therefore, the condensed water falling through the inner protruding rib 136 may fall downstream from the flow guider 124 and flow into the communication hole 122 .

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Various modifications and implementations are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

1: dishwasher 10: case
12: tub 14: base
100: supply device 102: supply fan
104: supply fan housing 105: expansion duct
106: heating duct 107: bottom plate
108: heater 114: supply duct
116: first supply duct 118: second supply duct
120: connection body 122: communication hole
140: water collector 142: overflow hole
144: water level sensor 146: inflow hole

Claims (12)

tub;
a supply fan supplying external air to the tub;
a heating duct disposed below the tub and having a heater to heat the air flowing from the supply fan;
a supply duct connected to the heating duct and supplying air flowing from the heating duct to one side of the tub;
and a water collecting device disposed under the heating duct and storing condensed water flowing from the supply duct. According to claim 1,
A communication hole communicating with the water collecting device is formed in the heating duct,
The communication hole is disposed closer to the supply duct than to the supply fan. According to claim 1,
The dishwasher of claim 1 , wherein an overflow hole is formed at one side of the water collecting device to communicate the inside and the outside. According to claim 3,
One side of the water collecting device includes a water level sensor for detecting the level of the condensed water stored therein,
The water level sensor is disposed above the overflow hole. According to claim 2,
The heating duct includes a bottom plate disposed below the heater and having a communication hole formed at one side thereof,
The bottom plate includes a first bottom plate disposed on an upstream side of the air flow direction based on the communication hole, and a second bottom plate disposed on a downstream side of the air flow direction based on the communication hole,
The second bottom plate is formed to be inclined downward as it is closer to the communication hole. According to claim 1,
The dishwasher of claim 1 , wherein a communication hole is formed at a lower side of the supply duct to send condensed water flowing through the supply duct to the water collecting device. According to claim 6,
The supply duct includes a first supply duct disposed in the lateral direction of the tub and forming an ascending passage, and a second supply duct having a bent connection passage to connect the heating duct having a horizontal passage and the first supply duct. A duct and a connection body disposed at an end of the second supply duct and having an opening communicating with the inside of the heating duct,
The communication hole is formed on the lower side of the second supply duct. According to claim 6,
The communication hole is formed at a position adjacent to the connection body,
The connection body has a stepped portion formed at a portion connected to the second supply duct. According to claim 6,
A communication hole is formed at the lower side of the second supply duct,
A flow guider is disposed upstream of the communication hole to guide the air flowing from the heating duct to the first supply duct. According to claim 9,
A bent connection passage is formed inside the second supply duct,
The second supply duct includes an upper wall disposed above the connection passage and a lower wall disposed below the connection passage,
The upper wall includes an upper vertical wall extending in a vertical direction, an upper horizontal wall connected to the heating duct and extending in a horizontal direction, and an upper bending wall connecting the upper vertical wall and the upper horizontal wall,
The lower wall includes a lower vertical wall formed in a direction parallel to the upper vertical wall, a lower horizontal wall disposed downward in parallel with the upper horizontal wall, and a lower bending wall connecting the lower vertical wall and the lower horizontal wall. include,
The dishwasher of claim 1 , wherein an inner protruding rib protruding downward is disposed at a lower end of the upper vertical wall. According to claim 10,
The inner protruding rib extends in left and right directions and protrudes downward in the form of a screw thread. According to claim 11,
A flow guider is disposed on the lower horizontal wall, and the communication hole is formed downstream of the flow guider,
The distance between the inner protruding ribs from the opening is longer than the distance between the end of the flow guider and the opening.

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